CN216947191U - Continuous ALD coating equipment - Google Patents

Abstract

The utility model provides continuous ALD coating equipment, and relates to the technical field of atomic layer deposition. The continuous ALD coating equipment comprises a box body assembly, a vacuum assembly and a driving assembly. The box body assembly comprises a heating cavity, a connecting cavity and a cooling cavity which are connected in sequence. The heating cavity is provided with a heating chamber. A film coating chamber used for coating the workpiece is arranged in the connecting cavity. The cooling cavity is provided with a cooling chamber. The heating chamber and the cooling chamber can be respectively communicated with the film coating chamber. The vacuum assembly is connected with the box body assembly for vacuumizing. The driving assembly is connected with the box body assembly and used for driving the workpiece to move among the heating chamber, the coating chamber and the cooling chamber. The box body assembly further comprises a first access door configured in the connecting cavity. The heating, the coating and the cooling in the coating process are respectively carried out in the three cavities, and the three cavities can work simultaneously, so that the working efficiency of the coating equipment is greatly improved.

Description

Continuous ALD coating equipment

Technical Field

The utility model relates to the technical field of atomic layer deposition, in particular to continuous ALD coating equipment.

Background

Atomic layer deposition (Atomic layer deposition) is a process by which a substance can be deposited on a substrate surface layer by layer as a monoatomic film. In an atomic layer deposition process, the chemical reaction of a new atomic film is directly related to the previous one in such a way that only one layer of atoms is deposited per reaction. Also, the deposited layer has an extremely uniform thickness and excellent uniformity.

An ALD coating process comprising: 1. putting a wafer disc (a silicon wafer, namely a coating product) into coating equipment; 2. heating the temperature in the coating equipment to a reaction temperature; 3. introducing a precursor A into the coating equipment; 4. removing the precursor A in the coating equipment to enable the surface of the wafer plate to adsorb a layer of precursor A; 5. Introducing a precursor B into the coating equipment; 6. and removing the precursor B in the coating equipment, reacting the precursor A on the surface of the wafer disc with the precursor B, and coating a required atomic layer on the surface of the wafer disc.

In the prior art, a wafer disc is usually placed in a chamber of a coating apparatus, and then the above steps are performed in sequence, so as to complete coating on the wafer disc. The period of the whole film coating process is long, and the production efficiency is low.

In view of the above, the applicant has specifically proposed the present application after studying the existing technologies.

SUMMERY OF THE UTILITY MODEL

The utility model provides continuous ALD coating equipment, aiming at solving the technical problem of insufficient cleanliness in the ALD coating process.

In order to solve the above technical problems, the present invention provides a continuous ALD coating apparatus, which comprises a box assembly, a vacuum assembly, and a driving assembly.

The box body assembly comprises a heating cavity, a connecting cavity and a cooling cavity which are connected in sequence. The heating cavity is provided with a heating chamber. A film coating chamber used for coating the workpiece is arranged in the connecting cavity. The cooling cavity is provided with a cooling chamber. The heating chamber and the cooling chamber can be respectively communicated with the film coating chamber. The vacuum assembly is coupled to the box assembly for drawing a vacuum so that the heating chamber and the cooling chamber can be vacuum-connected to the coating chamber. The driving assembly is connected with the box body assembly and used for driving the workpiece to move among the heating chamber, the coating chamber and the cooling chamber. The box body assembly further comprises a first access door configured in the connecting cavity.

By adopting the technical scheme, the utility model can obtain the following technical effects:

the ALD coating equipment is arranged into the heating cavity, the connecting cavity and the cooling cavity which are sequentially connected, the heating, the coating and the cooling in the coating process are respectively carried out in the three cavities, and the three cavities can simultaneously work, so that the working efficiency of the coating equipment is greatly improved.

Drawings

FIG. 1 is an isometric view of a continuous ALD coating apparatus;

FIG. 2 is a half-sectional view of a continuous ALD coating apparatus;

FIG. 3 is an exploded view of the connecting chamber;

FIG. 4 is an exploded view of the interior of the connecting chamber;

FIG. 5 is an exploded view of a coating chamber;

FIG. 6 is an exploded view of the coating chamber (hidden box);

FIG. 7 is an isometric view of the cooling chamber;

FIG. 8 is a first exploded view of the drive member;

FIG. 9 is a second exploded view of the drive member;

FIG. 10 is an exploded view of the ratchet mechanism;

FIG. 11 is an exploded view of the boat assembly;

FIG. 12 is a first exploded view of the slat door;

fig. 13 is a second exploded view of the slat door.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be described in detail and completely with reference to the accompanying drawings.

The utility model is described in further detail below with reference to the following detailed description and accompanying drawings:

referring to fig. 1 to 13, an embodiment of the present invention provides a continuous ALD coating apparatus, which includes a box assembly, a vacuum assembly, and a driving assembly.

The box body component comprises a heating cavity 12, a connecting cavity 5 and a cooling cavity 9 which are connected in sequence. The heating chamber 12 is provided with a heating chamber 6. A coating cavity 10 for coating the workpiece is arranged in the connecting cavity 5. The cooling cavity 9 is provided with a cooling chamber 3. The heating chamber 6 and the cooling chamber 3 can be respectively communicated with the coating chamber 10. The vacuum assembly is coupled to the tank assembly to draw a vacuum so that the heating chamber 6 and the cooling chamber 3 can be vacuum-connected to the coating chamber 10. The drive assembly is coupled to the box assembly for driving the workpiece to move between the heating chamber 6, the coating chamber 10 and the cooling chamber 3.

The coating equipment in the prior art usually has only one chamber, and the product is required to be put into the chamber, and then taken out after three steps of temperature rise, coating and cooling so as to complete the coating operation. The continuous ALD coating equipment disclosed by the utility model not only carries out the three steps of heating, coating and cooling respectively in different cavities through the heating cavity 12, the connecting cavity 5 and the cooling cavity 9 which are connected in sequence, so that the coating cavity 10 is always in coating operation, and the coating production efficiency is greatly improved. And through the vacuum assembly, make heating chamber 6 and cooling chamber 3 can be connected with coating film cavity 10 vacuum respectively for coating film cavity 10 can not contact the air, avoids the entering of impurity, has improved the cleanliness factor among the coating film process greatly, has improved the quality of product.

In an alternative embodiment, as shown in figures 2 and 3, the housing assembly comprises a coating chamber 4 provided with a coating chamber 10. The connection chamber 5 is provided with a connection chamber 11. The coating chamber 4 is disposed in the connection chamber 11, and the coating chamber 10 can communicate with the heating chamber 6 and the cooling chamber 3 through the connection chamber 11. The vacuum assembly is respectively communicated with the heating chamber 6, the cooling chamber 3, the connecting chamber 11 and the coating chamber 10 for vacuum pumping, so that the heating chamber 6 and the cooling chamber 3 can be connected to the coating chamber 10 through the connecting chamber 11 in a vacuum mode.

It can be understood that the coating chamber 10 needs to be cleaned periodically to further ensure the coating quality because reactants are generated in the coating chamber 10 during the coating process. In the embodiment, a coating cavity 4 is detachably mounted inside the connecting cavity 5, so that the coating cavity 10 is convenient to clean.

Specifically, a connecting chamber 11 for communicating the heating chamber 6 and the cooling chamber 3 is provided inside the connecting chamber 5. The coating cavity 4 is arranged in the connecting chamber 11, and the openings at two sides of the coating cavity are respectively opposite to the heating chamber 6 and the cooling chamber 3. The heated workpiece in the heating chamber 6 can directly enter the coating chamber 10 in the connecting chamber 11 after being moved out of the heating chamber 6; and the workpiece coated by the coating chamber 10 can directly enter the cooling chamber 3 communicated with the connecting chamber 11 after being moved out of the coating chamber 10. And, the heating chamber 6 and the cooling chamber 3 can be vacuum-connected to the coating chamber 10 through the connection chamber 11, thereby improving the cleanliness of the coating process.

Preferably, the box body assembly further comprises a first access door 1 arranged in the connecting cavity 5; the first access door 1 is used for taking and placing the coating cavity 4. The box body assembly further comprises a second access door arranged on the heating cavity 12 and a third access door arranged on the cooling cavity 9.

In an alternative embodiment, as shown in fig. 3 to 6, the coating cavity 4 is provided with a material feeding hole 21 at the top and a material discharging hole 23 at the bottom, which are communicated with the coating chamber 10.

The box assembly further comprises a bellows 19 coupled to the connection chamber 5, a connection plate 20 coupled to the bellows 19, a feed pipe 17 coupled to the connection plate 20, and a first telescopic jacking member 18 engageable between the connection plate 20 and the connection chamber 5. The connection plate 20 is provided with a connection through hole 30 communicating with the bellows 19. The delivery pipe 17 is hermetically connected to the connecting through hole 30 and extends to the outside of the connecting cavity 5 through the corrugated pipe 19. The first telescopic abutting member 18 is used for abutting the connecting plate 20 on the coating chamber 4, so that the connecting through hole 30 is hermetically connected to the feeding hole 21.

The bottom of the connection chamber 5 is provided with a first connection hole 15 communicating with the connection chamber 11. The coating cavity 4 is located above the first connection hole 15, so that the discharge hole 23 is connected to the first connection hole 15 in a sealing manner. The vacuum assembly is coupled to the first connection hole 15 for evacuating the coating chamber 10. The box assembly further comprises a second telescopic jacking member 13 which can be jointed between the film coating cavity 4 and the connecting cavity 5. The second telescopic jacking member 13 is configured to: for abutting the coating chamber 4 against the bottom of the connection chamber 11.

Specifically, the top of the coating cavity 4 is fed, and the bottom is discharged. Arrange material hole 23 and first connecting hole 15 and set up respectively in coating film cavity 4 and the bottom of connecting cavity 5, in sealing connection row material hole 23 and first connecting hole 15, only need place coating film cavity 4 and just can accomplish sealing connection on the bottom surface of connecting cavity 11, simple structure, easy dismounting has fine practical meaning.

Preferably, only one first connection hole 15 is formed in the bottom of the connection chamber 5, and the vacuum assembly (not shown) includes a discharge pipe coupled to the first connection hole 15, a first vacuum barrier 27 valve disposed in the discharge pipe, two second vacuum barrier 27 valves connected in parallel to the discharge pipe, and two vacuum pumps coupled to the two second vacuum barrier 27 valves, respectively.

Particularly, the utility model discloses a discovery through a large amount of researches, thereby precursor A and precursor B can take place the reaction in the vacuum pump and lead to the vacuum pump to damage, need frequent maintenance. Even if the filter device is installed in front of the vacuum pump to filter one of the precursors, the filter device can affect the flow rate of the fluid in the discharge pipeline, greatly reduce the vacuum pumping speed, and the filter device also needs to be frequently replaced to ensure the filtering effect.

In view of this, the embodiment of the present invention extracts the precursor a and the precursor B in the coating chamber 10 through the two vacuum valves via the discharge pipe, so as to prevent the precursor a and the precursor B from reacting in the vacuum pump, greatly prolong the service life of the vacuum structure, and have a very good practical significance.

Preferably, the connecting chamber 11, the heating chamber 6 and the cooling chamber 3 are respectively communicated with a small vacuum pump through pipelines for vacuumizing, so that the heating chamber 6, the connecting chamber 11, the coating chamber 10 and the cooling chamber 3 are kept in a vacuum state for independently operating, and the cleanliness of the coating process is ensured.

The feeding pipe 17 is connected with the upper surface of the coating cavity 4 through a quick-release structure; specifically, the inside of the connection chamber 11 is always in a vacuum state. Therefore, it is necessary to use a corrugated pipe 19 to cover the feed pipe 17 to prevent the feed pipe 17 from being broken. In this embodiment, a plurality of material delivery pipes 17 are connected to one connecting plate 20, and when the material delivery pipes 17 are installed in the coating cavity 4, only the connecting plate 20 needs to be hermetically pressed on the top of the coating cavity 4, so that the plurality of material delivery pipes 17 can be simultaneously and respectively and hermetically connected to the plurality of material delivery holes 21, thereby rapidly and simultaneously disassembling and assembling the plurality of material delivery pipes 17, and greatly facilitating the taking and placing of the coating cavity 4.

In this embodiment, the first and second telescopic jacking members 18 and 13 have the same structure, and each of the first and second telescopic jacking members includes a stud with a clamping position in the middle and two ejector rods respectively connected to two ends of the stud in a threaded manner, and the telescopic jacking members extend by rotating the ejector rods and the stud, so as to jack the connecting plate 20 to the top of the coating cavity 4 and jack the coating cavity 4 to the bottom of the connecting chamber 11.

In the present embodiment, the number of the connecting through holes 30, the number of the corrugated pipes 19 and the number of the material conveying pipes 17 are one-to-one, and at least two. Wherein at least one feed delivery pipe 17 is used for the first precursor to pass through. At least one feed conveyor 17 is provided for the passage of the second precursor. Specifically, the number of the material conveying pipes 17 is two, and the material conveying pipes are used for conveying the precursor a and the precursor B, respectively, but the connecting plate 20 may also be provided with a digital pressure sensor, a vacuum gauge, a thermocouple, and other measuring devices to measure environmental parameters inside the coating chamber 10, which is not limited in the present invention.

In an alternative embodiment, as shown in fig. 3 to 6, the top of the coating chamber 4 is provided with a sealing surface 22 for engaging the connecting plate 20, and a feed hole 21 provided on the sealing surface 22 and communicating with the coating chamber 10. The sealing surface 22 is arranged along the direction of the coating chamber 4 entering and exiting the first access door 1. The box assembly further includes at least two carriers 24 disposed on either side of the sealing surface 22. External equipment can act on the carrier 24 to remove the coating chamber 4 from the connecting chamber 11.

Specifically, the carrying member 24 is in a rectangular ring shape and is used for matching with external equipment such as a forklift so as to take and place the coating chamber 4 from the connecting chamber 11. The sealing surface 22 is arranged between the conveying pieces 24, so that when the coating cavity 4 enters and exits the connecting chamber 11, the connecting plate 20 and other parts cannot interfere with the conveying pieces 24, and the coating cavity 4 can be taken and placed more conveniently.

In an alternative embodiment, as shown in fig. 5 and 6, a feed slot 29 is provided at the top of the coating chamber 10 and communicates with the feed delivery hole 21. The housing assembly further includes a baffle 27 for covering the feed slot 29 and a flow equalizing plate 26 disposed at the top of the coating chamber 10. The baffle 27 is provided with a plurality of discharge through holes 28. The flow equalizing plate 26 is distributed with a plurality of flow equalizing through holes 25.

Specifically, the coating cavity 4 is composed of a cavity main body and a cavity top cover; the sealing surface 22 and the feed delivery hole 21 are both provided on the chamber top cover. The cavity top cover is provided with two material conveying holes 21 and two material supply grooves 29 respectively communicated with the two material conveying holes 21. The feeding groove 29 is a transverse groove and a plurality of grooves which are arranged at intervals and are communicated with the transverse groove and are in a Chinese character shan shape, and the grooves are formed by vertical grooves, so that the whole cavity top cover is full of the feeding groove, and the precursor can be distributed on the whole cavity top cover through the feeding groove 29 after passing through the material conveying hole 21.

Two layers of netted flow equalizing plates 26 are further arranged on the top cover of the cavity in a stacking mode, the precursor flowing out of the discharging through hole 28 communicated with the feeding groove 29 flows to the flow equalizing plates 26, and the precursor can be distributed more uniformly in the coating cavity 10 through the two layers of flow equalizing plates 26, and the flow rate of the precursor can be greatly increased. The problem of insufficient reaction caused by precursor aggregation and too high flow rate is solved, and the method has good practical significance.

In an alternative embodiment, as shown in fig. 3, the box assembly further comprises a positioning member 16 arranged at the bottom of the connection chamber 11. The positioning member 16 is configured to: the position of the coating chamber 10 in the connection chamber 11 can be limited. Specifically, the positioning member 16 includes a plurality of positioning blocks disposed at the bottom of the connection chamber 11. A limiting space for accommodating the film coating cavity 4 is formed among the positioning blocks. The locating piece is provided with the direction inclined plane towards spacing space.

In this embodiment, the positioning member 16 includes 8 positioning blocks, which are respectively disposed at four corners of the coating chamber 4. The positioning blocks provided in the direction toward the cooling chamber 3 and the heating chamber 6 are lower in height than the positioning blocks provided in the direction toward the access door.

In an alternative embodiment, as shown in FIGS. 2 and 3, the continuous ALD coating apparatus further includes a sealing assembly. The sealing assembly comprises six gate inserts 2 arranged in the box assembly. The first inserting plate door 2 and the second inserting plate door 2 are respectively used for communicating the film coating chamber 10 and the connecting chamber 11. The third gate 2 is used to connect the heating chamber 6 and the connecting chamber 11. The fourth gate 2 is used to connect the connection chamber 11 and the cooling chamber 3. The fifth inserting plate door 2 is used for communicating the heating chamber 6 and the outside of the heating cavity 12. The sixth gate 2 is used to communicate the cooling chamber 3 with the outside of the cooling chamber 9.

Preferably, six of the gate-boards 2 are arranged along the vertical direction, so that a U-shaped structure is formed between the first gate-board 2 and the second gate-board 2 and the connecting chamber 11, a U-shaped structure is formed between the third gate-board 2 and the fifth gate-board 2 and the heating chamber 12, and a U-shaped structure is formed between the fourth gate-board 2 and the sixth gate-board 2 and the cooling chamber 3.

Specifically, the six inserting plate doors 2 can isolate the heating chamber 6, the connecting chamber 11, the coating chamber 10 and the cooling chamber 3 from each other and work independently. And the length of the whole coating film can be greatly shortened, the moving distance of the workpiece in the whole production process is shortened, the internal structure of the coating equipment is simplified, and the occupied area can be reduced.

Preferably, the first inserting plate door 2 and the second inserting plate door 2 are configured in the connecting cavity 5 and can be separated from the coating cavity 4 when the door is opened, so that the number of parts on the coating cavity 4 is reduced, the structure of the coating cavity 4 is simplified, and the coating cavity 4 is convenient to disassemble and assemble. The third and fifth inserting doors 2 and 2 are disposed in the heating chamber 12. The fourth gate 2 and the fourth gate 2 are arranged in the cooling chamber 9. Specifically, the three cavities of the heating cavity 12, the connecting cavity 5 and the cooling cavity 9 are mutually independent and assembled together to form the coating equipment, so that the production of the coating equipment is greatly facilitated.

Preferably, the first and third slatted doors 2, 2 are parallel. So that the heated workpiece in the heating chamber 6 can directly pass through the first inserting plate door 2 and the third inserting plate door 2 to enter the coating chamber 10. The second and fourth gate 2 are parallel. So that the coated workpiece in the coating chamber 10 can directly pass through the second and fourth inserting plate doors 2 and enter the cooling chamber 3. The first and second gate inserts 2 and 2 are parallel so that the heating chamber 12, the connecting chamber 5 and the cooling chamber 9 are connected in sequence along a straight line. The workpiece moves along a straight line in the whole coating equipment, so that the structure of the driving assembly and the moving path of the workpiece are greatly simplified.

It is understood that the fifth and sixth patch panels 2, 2 may be other types of patch panels 2, and the second and third patch panels 2, 2 may also be mounted on the connecting cavity 5, which is not limited in this respect.

As shown in fig. 12 and 13, in an alternative embodiment, the slatted door 2 includes a drive plate 60 movable up and down on the cavity, a link 66 hinged to the drive plate 60, a sealing plate 65 hinged to the link 66, and a telescopic drive member 58 coupled to the drive plate 60. The telescopic drive 58 is capable of driving the drive plate 60 downward to below the seal plate 65 against an external object. The telescopic drive 58 also drives the drive plate 60 further downwards, thereby rotating the connector 66 and driving the sealing plate 65 laterally to seal against the opening of the cavity. Wherein the drive plate 60 and the connector 66 are hingedly connected to the a-axis. The seal plate 65 and the connecting member 66 are hinged to the B-axis. The A and B axes lie in the C plane. The inserting plate door 2 is constructed as follows: when the driving plate 60 moves up and down, the included angle D between the plane where the driving plate 60 is located and the plane C is always smaller than 90 degrees.

Specifically, the drive plate 60, the seal plate 65, and the connecting member 66 form a link structure therebetween. The telescopic driving member 58 drives the driving plate 60 to move up and down, and simultaneously drives the sealing plate 65 to move up and down through the connecting member 66. When the telescopic driving member 58 drives the driving plate 60 to move downwards, the bottom of the sealing plate 65 is firstly abutted to the bottom surface of the chamber, then the telescopic driving member 58 continues to drive the driving plate 60 to move downwards, and at the moment, the sealing plate 65 does not move downwards continuously but becomes horizontal under the action of the connecting member 66 until abutting against the side surface of the chamber, so that the opening of the chamber is sealed. When the telescopic driving member 58 drives the driving plate 60 to move downwards, the sealing plate 65 drives the connecting member 66 to rotate under the action of gravity, so that the sealing plate moves horizontally to be away from the side surface of the chamber and approach the driving plate 60, and when the sealing plate 65 abuts against the driving plate 60, the sealing plate does not move horizontally any more and moves upwards along with the driving plate 60, so that the opening of the chamber is completely opened.

Because contained angle D is less than 90 degrees all the time, consequently under the state of closing the door, the decurrent drive power of cylinder has partly to turn into the drive power of horizontal drive closing plate 65 laminating on the cavity all the time, guarantee that can be fine sealed effect even sealing washer between closing plate 65 or closing plate 65 and the cavity lateral wall takes place wearing and tearing and also can not influence sealed effect, has fine practical meaning.

Preferably, the telescopic driving member 58 is an air cylinder, the first inserting plate door 2 and the second inserting plate door 2 are installed in the connecting chamber 11, the third inserting plate door 2 is installed in the heating chamber 6, and the fourth inserting plate door 2 is installed in the cooling chamber 3, both of which are in a vacuum environment, so as to avoid air leakage of the air cylinder, and therefore, the output shaft of the telescopic driving member 58 is sleeved by the bellows 19.

In an alternative embodiment, as shown in fig. 12 and 13, the slatted door 2 further includes a roller mechanism 63 and a stop block 59. The roller mechanism 63 is disposed in the casing below the sealing plate 65, and is capable of limiting the limit position of the sealing plate 65 when the sealing plate 65 moves downward and reducing the friction force when the sealing plate 65 moves laterally. The limiting block 59 is configured on the driving plate 60 or the cavity, and is used for limiting the baseline position of the driving plate 60 when moving upwards. The tailgate door 2 further includes a sliding support plate 62 disposed at a lower end of the sealing plate 65. The sliding support plate 62 is used to abut against the roller mechanism 63.

Specifically, the stopper 59 may be installed at a position where the driving plate 60 faces upward, or may be disposed at a position on the cavity where the driving plate 60 reaches when moving upward, so as to stop the driving plate 60 when the driving plate 60 moves to the highest point. The roller mechanism 63 includes a base and a plurality of rollers disposed on the base. The sliding support plate 62 is mounted on the bottom surface of the sealing plate 65 to abut against the roller, so that when the sealing plate 65 moves horizontally, the sliding support plate is rolled instead of sliding, and the resistance to the horizontal movement of the sealing plate 65 is reduced.

In an alternative embodiment, shown in fig. 12 and 13, the slatted door 2 further includes rollers 67 disposed on the sides of the drive plate 60. The roller 67 is located on the axis a for sliding up and down the chute 14 in the cavity. Specifically, the cavity is provided with sliding grooves 14 on two sides of the opening. The gate 2 has a rotation shaft on a side of the driving plate 60. The connecting member 66 and the rolling member 67 are sequentially provided on the rotating shaft, and the rolling member 67 is a bearing for sliding up and down on the chute 14 of the cavity.

Preferably, the sealing plate 65 is provided with a hinge portion 64 extending towards the drive plate 60. The hinge portion 64 is configured to abut against the drive plate 60 when the seal plate 65 approaches the drive plate 60. The connecting member 66 is hinged to the hinge portion 64. The drive plate 60 is provided with a stopper portion 61 extending toward the seal plate 65. The stopper 61 is configured to abut against the sealing plate 65 when the sealing plate 65 approaches the driving plate 60. The telescopic driving member 58 is engaged with the stopper portion 61.

The hinge part 64 and the limit part 61 are set to have the same height, so that when the sealing plate 65 approaches the driving plate 60, the limit part 61 and the hinge part 64 are abutted, the contact area between the sealing plate 65 and the driving plate 60 is reduced, the generation of loud noise is avoided,

the thickness of the inserting plate door 2 can be greatly reduced by arranging the output shaft of the telescopic driving piece 58 between the driving plate 60 and the sealing plate 65, so that the length of the real film coating equipment and the distance of the workpiece needing to move in the film coating process are reduced, and the telescopic driving piece has good practical significance.

As shown in fig. 7 and 11, in an alternative embodiment, the drive assembly comprises two drive members 32 arranged respectively in the heating chamber 6 and in the cooling chamber 3. The driving member 32 disposed in the heating chamber 6 is configured to: can move left and right, thereby moving the workpiece outside the heating chamber 6 to the inside of the heating chamber 6 and moving the workpiece inside the heating chamber 6 to the coating chamber 10. The driving member 32 disposed in the cooling chamber 3 is configured to: can move left and right, thereby moving the workpiece in the coating chamber 10 to the cooling chamber 3 and moving the workpiece in the cooling chamber 3 to the outside of the cooling chamber 3.

Specifically, two driving members 32 are respectively arranged in the heating chamber 6 and the cooling chamber 3, so that only the guide rail member 8 and the flow equalizing plate 26 are arranged in the coating chamber 10, the structure is simple, the cleaning is convenient, the damage is not easy to damage, and the practical significance is good.

It will be appreciated that the precursor a and the precursor B react in the coating chamber 10 to form the desired coating, and also form a coating on the surfaces of the components in the coating chamber 10, so that the coating chamber 10, if having a transmission mechanism, is easily damaged and is not easy to clean. In the utility model, the carrying disc assembly 7 is moved among the five guide rail members 8 in sequence in a left-right moving mode, so that the heating, film coating and cooling operations of the workpiece are realized under the condition that no power mechanism is arranged in the film coating chamber 10, and the utility model has good practical significance.

As shown in fig. 8 and 9, in an alternative embodiment, the driving member 32 includes a first moving mechanism 34 capable of moving along a predetermined trajectory, a click mechanism 33 provided to the first moving mechanism 34, a transmission mechanism engaged with the first moving mechanism 34, and a driving mechanism 37 engaged with the transmission mechanism. The driving mechanism 37 can drive the first moving mechanism 34 to move forward or backward along a predetermined trajectory by the transmission mechanism. The click mechanism 33 is configured to: when the first moving mechanism 34 moves in the forward direction, the first moving mechanism can abut against an external object and avoid the external object, and when the first moving mechanism 34 moves in the reverse direction, the first moving mechanism can abut against the external object and drive the external object to move in the forward direction. Preferably, the drive member 32 comprises two pawl mechanisms 33. The two click mechanisms 33 are respectively disposed at both ends of the first moving mechanism 34. The click mechanism 33 includes a push plate 38 rotatably disposed on the first moving mechanism 34, and an elastic member 39 engaged between the push plate 38 and the first moving mechanism 34. The push plate 38 is provided with an abutting portion 55 for abutting against the first moving mechanism 34. The abutting portion 55 serves to position the push plate 38 when the first moving mechanism 34 moves reversely. The resilient member 39 is configured to urge the push plate 38 from the retracted position.

Specifically, the driving mechanism 37 and the transmission mechanism drive the first moving mechanism 34 to move left and right, so that the tray assembly 7 is hooked into the heating chamber 6 from the outside of the heating chamber 12 or pushed into the coating chamber 10 from the inside of the heating chamber 6 by the pawl structure on the first moving mechanism 34. The pawl mechanism 33 with a pure mechanical structure realizes the movement of the carrying disc assembly 7, can adapt to the vacuum high-temperature environment in the heating chamber 6 and is not easy to damage, and has good practical significance. It will be appreciated that two detent mechanisms 33 are provided at each end of the first moving mechanism 34, one for hooking and the other for pushing out, and that both push plates 38 are used to apply force in the same direction.

As shown in fig. 8 and 9, in an alternative embodiment, the driving member 32 further includes a second moving mechanism 35, and the second moving mechanism 35 is coupled to the transmission mechanism and configured to be driven by the transmission mechanism to move forward or backward along a predetermined trajectory. The first moving mechanism 34 is configured to: when the second moving mechanism 35 moves, the second moving mechanism 35 can move relative to the second moving mechanism 35 in the moving direction of the second moving mechanism 35. Preferably, the drive member 32 further includes a base mechanism 36. The base mechanism 36 is configured to be disposed in the heating chamber 6 or the cooling chamber 3. The second moving mechanism 35 is slidably disposed on the base mechanism 36. The first moving mechanism 34 is slidably disposed on the second moving mechanism 35.

Specifically, the distance of elongation when the driving member 32 moves left and right can be increased by the second moving mechanism 35, so that the tray assembly 7 is moved to a proper position with fewer hooking times, and the method has a good practical significance. The first moving mechanism 34, the second moving mechanism 35 and the transmission mechanism can be integrated into a whole by the base mechanism 36, so as to facilitate the disassembling and assembling operation of the driving member 32.

As shown in fig. 8 and 9, in an alternative embodiment, the transmission mechanism includes a first gear 53 and a first rack 52 disposed on the base mechanism 36, a second gear 50 and a second rack 51 disposed on the second moving mechanism 35, and a third rack 49 disposed on the first moving mechanism 34. The first gear 53 is coupled to the second rack 51 and is drivingly connected to the driving mechanism 37 for driving the second moving mechanism 35 to move relative to the base mechanism 36. The second gear 50 is engaged with the first rack 52 and the third rack 49, respectively, to move the first moving mechanism 34 toward the moving direction of the second moving mechanism 35 while the second moving mechanism 35 is moving. Preferably, the first moving mechanism 34 includes a first base plate 40 and a plurality of first rollers 41 disposed on the first base plate 40. The base mechanism 36 includes a base support plate 46 and a plurality of second rollers 45 disposed on the base support plate 46. The second moving mechanism 35 includes a second base plate 44 and a roller mount 43 disposed on the second base plate 44. Guide grooves 42 for receiving the first roller 41 and the second roller 45 are respectively provided at both sides of the roller mounting seat 43.

Specifically, the first gear 53 drives the second rack 51 to move through a gear-rack transmission structure, and the second gear 50 drives the third rack 49 to move, so that the second moving mechanism 35 and the first moving mechanism 34 move towards the same direction at the same time, a longer extending distance and extending speed are realized, and the high-efficiency movable carrying tray assembly 7 is ensured.

In the present invention, the roller mount 43 is provided on the second moving mechanism 35, and the rollers are mounted on the first moving mechanism 34 and the base mechanism 36, thereby enabling the first moving mechanism 34 to be slidably mounted on the second moving mechanism 35, and the second moving mechanism 35 to be slidably mounted on the base mechanism 36, thereby enabling the drive member 32 to have a longer extension distance. As an equivalent alternative of the present invention, it is also within the scope of the present invention that both the first moving mechanism 34 and the second moving mechanism 35 can be slidably disposed on the base mechanism 36.

In an alternative embodiment, as shown in fig. 8 and 9, the drive mechanism 37 includes an electric motor 48 and a magnetic fluid vacuum seal actuator 47. The motor 48 is connected with the input end of the magnetic fluid vacuum sealing transmission device 47 in a transmission way. The transmission mechanism further comprises a first gear 53 for driving the second moving mechanism 35 to move, and at least one transmission gear 54 in transmission connection with the first gear 53 and the output end of the magnetic fluid vacuum sealing transmission device 47. The first gear 53 and the at least one transmission gear 54 are arranged in the vertical direction.

Specifically, the two transmission gears 54 are arranged, the power of the driving mechanism 37 can be transmitted to the second rack 51 positioned in the cavity from the bottom of the driven cavity to be driven through the first gear 53 and the two transmission gears 54 which are vertically arranged, the multi-stage gear transmission is adopted, the long service life can be kept in a high-temperature vacuum environment, and the practical significance is good.

In other embodiments, the transmission can be realized through structures such as a belt and a chain, which belong to the equivalent technical scheme of the embodiment and belong to the protection scope of the utility model.

As shown in fig. 2, 7 and 11, in an alternative embodiment, the cassette assembly further comprises a boat assembly 7 for carrying the workpiece and five rail members 8 for supporting the boat assembly 7. The five guide rail members 8 are respectively arranged in the heating chamber 6, the coating chamber 10 and the cooling chamber 3, and are positioned outside the heating cavity 12 and outside the cooling cavity 9. The boat assembly 7 is configured to: can be moved between the five rail members 8 by the drive assembly to pass through the heating chamber 12, the connecting chamber 5 and the cooling chamber 9 in that order. Preferably, the top of the pallet assembly 7 is provided with a placing groove for placing the workpiece, the bottom is provided with a driving groove 57 for hooking the pallet mechanism 33, and the pallet roller 56 can slide on the guide rail assembly. The guide rail assembly is provided with spacing grooves 31 at intervals for spacing the carrier disc rollers 56.

Specifically, the friction of the carrying disc assembly 7 in the moving process can be greatly reduced by adopting the running of the rollers, and the power required by the material moving device is greatly reduced. In other embodiments, the cooperating action may take the form of a chute 14. The utility model is not limited in this regard. Understandably, the friction force of the roller is small, and the shallow limiting groove 31 is arranged on the guide rail, so that the loading disc assembly 7 can be effectively prevented from disorderly sliding on the guide rail member 8 after the loading disc assembly 7 moves to the preset position.

Preferably, the box body assembly further comprises a coating chamber 10 and a heating structure of the heating chamber 6; specifically, a plurality of heating pipes are arranged on the top of the heating chamber 6 to heat the heating chamber 6. A heating plate is arranged on the side surface of the coating cavity 4; heating plates are also arranged on the first inserting plate door 2 and the second inserting plate door 2; a plurality of heating pipes and thermocouples are provided in the heating plate to heat the coating chamber 10. In this embodiment, the heating pipe and the thermocouple on the heating plate are connected by a quick-plugging port so as to facilitate the disassembly and assembly of the coating chamber 4.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A continuous ALD coating apparatus, comprising:

the box body assembly comprises a heating cavity (12), a connecting cavity (5) and a cooling cavity (9) which are connected in sequence; the heating cavity (12) is provided with a heating cavity (6); a film coating chamber (10) for coating a workpiece is arranged in the connecting cavity (5); the cooling cavity (9) is provided with a cooling cavity (3); the heating chamber (6) and the cooling chamber (3) can be respectively communicated with the coating chamber (10);

a vacuum assembly coupled to the box assembly for drawing a vacuum so that the heating chamber (6) and the cooling chamber (3) can be vacuum-connected to the coating chamber (10);

a drive assembly coupled to the box assembly for driving a workpiece to move between the heating chamber (6), the coating chamber (10) and the cooling chamber (3);

the box body assembly further comprises a first access door (1) configured on the connecting cavity (5).

2. A continuous ALD coating plant according to claim 1, characterized in that said tank assembly comprises a coating chamber (4) provided with said coating chamber (10); the connecting cavity (5) is provided with a connecting cavity (11); the coating cavity (4) is configured in the connecting chamber (11), and the coating chamber (10) can be communicated with the heating chamber (6) and the cooling chamber (3) through the connecting chamber (11);

the vacuum assembly is respectively communicated with the heating chamber (6), the cooling chamber (3), the connecting chamber (11) and the coating chamber (10) and is used for vacuumizing, so that the heating chamber (6) and the cooling chamber (3) can be connected with the coating chamber (10) in a vacuum mode through the connecting chamber (11).

3. The continuous ALD coating apparatus of claim 2, wherein the continuous ALD coating apparatus further comprises a sealing assembly; the sealing assembly comprises four spile doors (2); the first inserting plate door (2) and the second inserting plate door (2) are respectively used for communicating the film coating chamber (10) and the connecting chamber (11); a third flashboard door (2) for communicating the heating chamber (6) and the connecting chamber (11); a fourth bulkhead door (2) for communicating the connection chamber (11) with the cooling chamber (3); wherein the first and third slatted doors (2, 2) are parallel; the second inserting plate door (2) and the fourth inserting plate door (2) are parallel.

4. A continuous ALD coating plant according to claim 3, characterized in that said first shutter door (2) and said second shutter door (2) are arranged in said connection chamber (5); the third inserting plate door (2) is arranged in the heating cavity (12); the fourth flashboard door (2) is arranged in the cooling cavity (9); the first inserting plate door (2) and the second inserting plate door (2) are parallel, so that the heating cavity (12), the connecting cavity (5) and the cooling cavity (9) are sequentially connected along a straight line.

5. The continuous ALD coating equipment of claim 2, characterized in that the top of the coating cavity (4) is provided with a material conveying hole (21) communicated with the coating chamber (10);

the box body assembly further comprises a corrugated pipe (19) jointed with the connecting cavity (5), a connecting plate (20) jointed with the corrugated pipe (19), a conveying pipe (17) jointed with the connecting plate (20), and a first telescopic jacking member (18) jointed between the connecting plate (20) and the connecting cavity (5); the connecting plate (20) is provided with a connecting through hole (30) communicated with the corrugated pipe (19); the material conveying pipe (17) is hermetically connected with the connecting through hole (30) and penetrates through the corrugated pipe (19) to extend out of the connecting cavity (5); the first telescopic jacking member (18) is used for abutting the connecting plate (20) on the film coating cavity (4), so that the connecting through hole (30) is connected with the material conveying hole (21) in a sealing mode.

6. The continuous ALD coating equipment of claim 5, characterized in that the number of the connecting through holes (30), the corrugated pipes (19) and the conveying pipes (17) is one-to-one corresponding to at least two; wherein, at least one material conveying pipe (17) is used for the first precursor to pass through; at least one material conveying pipe (17) is used for the second precursor to pass through.

7. A continuous ALD coating equipment according to claim 2, characterized in that the bottom of the coating cavity (4) is provided with a discharge hole (23) communicated with the coating chamber (10); the bottom of the connecting cavity (5) is provided with a first connecting hole (15) communicated with the connecting cavity (11); the coating cavity (4) is positioned above the first connecting hole (15) so as to enable the discharge hole (23) to be connected with the first connecting hole (15) in a sealing manner; the vacuum assembly is coupled to the first connection hole (15) to evacuate the coating chamber (10).

8. A continuous ALD coating apparatus according to claim 7, characterized in that the box assembly further comprises a positioning member (16) arranged at the bottom of the connection chamber (11); the positioning member (16) is configured to: the position of the coating chamber (10) in the connecting chamber (11) can be limited;

the box body assembly also comprises a second telescopic jacking member (13) which can be jointed between the film coating cavity (4) and the connecting cavity (5); the second telescopic jacking member (13) is configured to: the coating cavity (4) is abutted to the bottom of the connecting cavity (11).

9. A continuous ALD coating apparatus according to any one of claims 2 to 8, characterized in that said drive assembly comprises two drive members (32) respectively arranged in said heating chamber (6) and said cooling chamber (3); a drive member (32) arranged to the heating chamber (6) is configured to: can move left and right, so as to move the workpiece outside the heating chamber (6) to the inside of the heating chamber (6) and move the workpiece inside the heating chamber (6) to the coating chamber (10); a drive member (32) disposed in the cooling chamber (3) is configured to: can move left and right, thereby moving the workpieces in the coating chamber (10) to the cooling chamber (3) and moving the workpieces in the cooling chamber (3) to the outside of the cooling chamber (3).

10. A continuous ALD coating apparatus according to any one of claims 2 to 8, characterized in that the box assembly further comprises a carrier tray assembly (7) for carrying the workpiece and five rail members (8) for supporting the carrier tray assembly (7); five guide rail members (8) are respectively arranged in the heating chamber (6), the coating chamber (10) and the cooling chamber (3) and are positioned outside the heating cavity (12) and outside the cooling cavity (9); the boat assembly (7) is configured to: can move between the five rail members (8) under the drive of the drive assembly so as to sequentially pass through the heating cavity (12), the connecting cavity (5) and the cooling cavity (9).

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